RESEARC H Open Access Vpx rescues HIV-1 transduction of dendritic cells from the antiviral state established by type 1 interferon Thomas Pertel, Christian Reinhard and Jeremy Luban * Abstract Background: Vpx is a virion-associated protein encoded by SIV SM , a lentivirus endemic to the West African sooty mangabey (Cercocebus atys). HIV-2 and SIV MAC , zoonoses resulting from SIV SM transmission to humans or Asian rhesus macaques (Macaca mulatta), also encode Vpx. In myeloid cells, Vpx promotes reverse transcription and transduction by these viruses. This activity correlates with Vpx binding to DCAF1 (VPRBP) and association with the DDB1/RBX1/CUL4A E3 ubiquitin ligase complex. When delivered experimentally to myeloid cells using VSV G- pseudotyped virus-like particles (VLPs), Vpx promotes reverse transcription of retroviruses that do not normally encode Vpx. Results: Here we show that Vpx has the extraordinary ability to completely rescue HIV-1 transduction of human monocyte-derived dendritic cells (MDDCs) from the potent antiviral state established by prior treatmen t with exogenous type 1 interferon (IFN). The magnitude of rescue was up to 1,000-fold, depending on the blood donor, and was also observed after induction of endogenous IFN and IFN-stimulated genes (ISGs) by LPS, poly(I:C), or poly (dA:dT). The effect was relatively specific in that Vpx-associated suppression of soluble IFN-b production, of mRNA levels for ISGs, or of cell surface markers for MDDC differentiation, was not detected. Vpx did not rescue HIV-2 or SIV MAC transduction from the antiviral state, even in the presence of SIV MAC or HIV-2 VLPs bearing additional Vpx, or in the presence of HIV-1 VLPs bearing all accessory genes. In contrast to the effect of Vpx on transduction of untreated MDDCs, HIV-1 rescue from the antiviral state was not dependent upon Vpx interaction with DCAF1 or on the presence of DCAF1 within the MDDC target cells. Additionally, although Vpx increased the level of HIV-1 reverse transcripts in MDDCs to the same extent whether or not MDDCs were treated with IFN or LPS, Vpx rescued a block specific to the antiviral state that occurred after HIV-1 c DNA penetrated the nucleus. Conclusion: Vpx provides a tool for the characterization of a potent, new HIV-1 restriction activity, which acts in the nucleus of type 1 IFN-treated dendritic cells. Background In addition to the gag, pol, and env genes common to all retroviruses, lentiviruses including HIV-1 bear specia- lized genes such as vp r that contribute to vi ral replica- tion and pathogenesis [1]. Simian immunodeficienc y viruses isolated from West African sooty mangabeys (SIV SM ) possess vpr as well as a highly homologous gene called vpx. The latter may have been generated by vpr gene duplication [2] or by recombination with an SIV that possessed a highly divergent vpx [3]. HIV-2 and SIV MAC , zoonoses derived from SIV SM ,alsopossess both of these genes. Neither vpr nor vpx is ess ential for virus replication in tissue culture, but both contribute to virus replication and disease progression in animal models [4,5]. The effect of these genes in vivo is possibly linked to their ability to enhance virus replication in dendritic cells and macrophages in tissue culture [6-15]. Myeloid cells are believed to be critical targets for lentiviruses in vivo, partly because they are capable of productive infection, but also because they facilitate virus transmission to CD4 + T-cells [16-18]. * Correspondence: jeremy.luban@unige.ch Department of Microbiology and Molecular Medicine, University of Geneva, Geneva, Switzerland Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 © 2011 Pertel et al; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited . Via interaction with short peptide signals in the car- boxy-terminus of the Gag polyprotein, the Vpr and Vpx proteins are incorporated into nascent virions as the particles exit productively infected cells [19-22]. The presence of these proteins within virions suggests that they play a role in the early steps of lentivirus infection, prior to de novo protein synthesis directed by transcripts from the n ew provirus. Vpr and Vpx promote reverse transcription soon after the virions enter the target cell cytoplasm [10,13,14]. Other studies suggested that Vpr and Vpx are required later in the retrovirus life cycle to promote nuclear import of the preintegration complex [23-26], though the significance of the latter findings have been questioned [27,28]. Attempts to saturate a hypothetical HIV-1-specific restriction factor in monocyte-derived dendritic cells (MDDC) using HIV-1 VLPs have led to the fortuitous discovery that SIV MAC VLPs increase HIV-1 reverse transcription and infectivity in these cells, so long as the VLPs possess Vpx [10,11,29]. Similar stimulation of infectivity was observed with proteasome inhibitors, sug- gesting that Vpx promotes the degradation of an anti- viral factor; CUL5-depen dent degradation of the antiviral protein APOBEC3G by the lentiviral accessory protein Vif offered compelling precedent for such a model [30-32]. Indeed, heterokaryon experiments sug- gested that myeloid cells possess a dominant-acting, Vpx-sensitive inhibitor of lentiviral infection [12]. Via direct binding to DCAF1 (also known as VPRBP), both Vpr and Vpx associated with the DDB1/RBX1/CUL4A E3 ubiquitin ligase complex [12,13,15,33-37]. Vpx mutants that do not bind DCAF1 are unable to stimu- late infectivity in myeloid cells [12,13,15]. Here, we report the results of experiments designed to determine the effect of Vpx on HIV-1 transduction of MDDCs in the face of the potent antiviral state pre- established by treatment with exogenous type 1 inter- feron (IFN) o r with agonists of pattern recogni tion receptor (PRRs) that stimulate endogenous type 1 IFN production and the transcription of interferon stimu- lated genes (ISGs). Results SIV MAC VLPs rescue HIV-1 infection from type I IFN The Vpx proteins of SIV MAC and HIV-2 promote trans- duction of myeloid cells by these viruses [6-15]. Though HIV-1 does not possess a gene encoding Vpx, the infec- tivity of HIV-1 in myeloid cells is also increased by SIV virus-like particles (VLPs) bearing Vpx [10,11,29]. Inter- est in potential links between retroviral restriction fac- tors and innate immune signaling [38,39] directed us to explore the effect of Vpx on HIV-1 transduction of myeloid cells after an antiviral state had been established by administration of exogenous type 1 IFN. Human monocyte-derived dendritic cells (MDDC) were generated by culture of CD14 + peripheral blood cells in GM-CSF and IL-4 for 4 days, as previously described [39]. The status of differentiation and matura- tion was confirmed by observing the typical morphology and by assessing immunofluorescence for standard cell surface markers, including CD1A, CD209 (DC-SIGN), CD14, CD11C, HLA-DR, CD83, and CD86 (additional file 1, Figure S1A and data not shown). When immature MDDCs were challenged with three-part, HIV-1-GFP reporter virus, pseudotyped with vesicular stomatitis virusglycoprotein(VSVG),SIV MAC VLPs increased transduction efficiency 3- to 10-fold (Figure 1A, upper panels), depending u pon the multiplicity of infection. Challenge of MDDC with HIV-1-GFP 24 h after treat- ment with exogenous IFN-a resulted in infection levels at or below the detection limit (Figure 1A, lower left panel). In the particular experiment shown in Figure 1, the magnitude inhibition of HIV-1 transduction by IFN- a was ≥ 600-fold. Addition of SIV MAC VLPs to the MDDCs 24 h after IFN-a treatment rescued HIV-1 transduction to levels at least as high as those in the absence of IFN-a (Figure 1 A, lower right panel). Identi- cal results were obtained when IFN-b was substituted for IFN-a (Figure 1B). SIV MAC VLPs rescue HIV-1 transduction of MDDC from LPS, poly(I:C), or poly(dA:dT) Lipopolysaccharide (LPS), the synthetic double-stranded RNA poly(I:C), and the synthet ic double-stranded DNA, poly(dA:dT), each activate IFNB1 transcription and establish a generalized antiviral state [39-42]. Treatment of MDDC with LPS, poly(I:C), or poly(dA:dT) indeed resulted in the production of soluble IFN-b (additional file 1, Figure S1B), the synthesis of intracellular MX1 and APOBEC3A proteins (additional file 1, Figure S1C), the transcriptional induction of IFNB1 and other inflam- matory genes, including MX1, CCL2, CCL8, CXCL10, IL6, ISG54 (IFIT2), PTGS2,andTNF (additional file 1, Figure S1D), as well as the upregulation of M DDC cell surface maturation markers, including CD86 and CD83 (additional file 1, Figure S1A). Since LPS, poly(I:C), and poly(dA:dT) all elicited type 1 IFN in MDDCs, the a bility of each to inhibit HIV-1 transduction was examined. MDDCs were treated for 24 h with either LPS, poly(I:C), or poly(dA:dT) and then challenged with VSV G-pseudotyped HIV-1-GFP repor- ter virus. Each of the treatments potently inhibited HIV- 1-GFP transduction (Figure 2A). When SIV MAC VLPs were added to the culture 24 h after treatment with any of the PRR agonists, HIV-1-GFP two-part vector trans- duction was rescued completely (Figure 2A). Similar results were observed when HIV-1 entry was mediated by CCR5-tropic HIV-1 Env, indicating that the effect of Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 2 of 16 Vpx was not peculiar to VSV G-pseudotyped HIV-1 (Figure 2B). The SIV MAC VLPs had no detectable effect on IFN-b secretion, MX1 or APOBEC3A protein pro- duction, cell-surface levels of MDDC maturation mar- kers, or mRNA induction of IFNB1 and a panel of 8 ISGs (additional fi le 1, Fig ure S1). Thes e findings indi- cate that the effect of the SIV MAC VLPs was relatively specific and that the VLPs did not globally reverse the antiviral state associated with type 1 IFN. Vpx is necessary and sufficient to protect HIV-1 from the type I IFN response Vpx is essential for the boost in HIV-1 transduction of human MDDCs that is provided by SIV MAC VLPs [10,11,29]. To determine if Vpx is also required f or the protective effect of VLPs in the context of the type 1 IFN-associated antiviral state, VLPs bearin g Vpx were compared with VLPs lacking Vpx. Either SIV MAC VLPs or HIV-2 VLPs rescued a three-part HIV-1 vector from A SSC -H HIV-1 transduced (% GFP + ) 12.7 % 39.5 % control SIV MAC VLPs 200 400 600 800 1000 200 400 600 800 1000 0.02 % 21.7 % IFN α IFN α + SIV MAC VLPs 200 400 600 800 1000 200 400 600 800 1000 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 B control IFN- β 10 -1 10 0 10 1 10 2 control SIV MAC VLPs HIV-1 transduced (% GFP + ) Figure 1 SIV MAC virus-like particles (VLPs) rescue H IV-1 transduction of human monocyte-derived dendritic cells (MDDCs) from pretreatment with type I ifN. MDDCs were incubated for 24 h with 10 ng⁄mL IFN-a (A)or10ng⁄mL IFN-b (B). The cells were then treated for 3 h with media or VSV-G-pseudotyped SIV MAC-251 VLPs, followed by challenge with a VSV-G-pseudotyped HIV-1 NL4-3 GFP reporter virus. The percent GFP-positive cells was determined by flow cytometry 72 h after transduction. Error bars represent ± standard deviation (SD) (n = 3). In each case, one representative example of at least three independent experiments is shown. Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 3 of 16 type 1 IFN or LPS treatment in human MDDC, but only when Vpx was present (Figure 3A). The same results were obtained if vpx was provided in cis or in trans with respect to the SIV structural proteins during assembly of the VLPs (additional file 2, Figure S2A), if Vpx was delivered by VLPs or w hole SIV vir us (addi- tional file 2, Figure S2B), or if Vpx was encoded by HIV-2 ROD ,SIV MAC251 ,SIV MAC239 ,orSIV SMM-PBJ (data not shown). Vpr encoded by SIV MAC , HIV-2, SIV AGM or HIV-1 did not rescue HIV-1 from the antiviral state and, if anything, decreased the efficiency of rescue by Vpx (additional file 2, Figure S2B). HIV-1 Gag p6 lacks the carboxy-terminal D-X-A-X-X- L-L peptide found in SIV MAC and HIV-2 Gag that A control IFN-α IFN-β LPS poly(I:C) poly(dA-dT) 10 -2 10 -1 10 0 10 1 10 2 SIV MAC VLP s control HIV-1 transduced (% GFP + ) CCR5 tropic Env B control LPS IFN- β 10 -2 10 -1 10 0 10 1 10 2 control SIV MAC VLPs HIV-1 transduced (% GFP + ) Figure 2 SIV MAC VLPs rescue HIV-1 infectivity from pretreatment of MDDC with pattern recognition receptor (PRR) agonists.(A) MDDCs were incubated for 24 h with recombinant type I interferon (10 ng⁄mL IFN-a,10ng⁄mL IFN-b), or PRR agonists as indicated: 100 ng⁄mL LPS, 25 μg⁄mL poly(I:C) with no lipid carrier, or 2 μg⁄mL poly(dA-dT). Then, cells were treated for 3 h with media or VSV-G-pseudotyped SIV MAC-251 VLPs, followed by challenge with a VSV G-pseudotyped HIV-1 NL4-3 GFP reporter virus (A) or with a CCR5-tropic, HIV-1 NL4-3 GFP reporter virus (B). The percent GFP- positive cells was determined by flow cytometry 72 h after addition of the reporter virus. Error bars represent ± SD (n = 3). In each case, one representative example of at least three independent experiments is shown. A control HIV-2vpx + VLPs HIV-2Δvpx VLPs SIV MAC vpx + VLPs SIV MAC Δvpx VLPs 10 -1 10 0 10 1 10 2 HIV-1 transduced (% GFP + ) control LPS B HIV-1 virions p24 Vpx Producer cell lysate p24 Vpx Gag WT: Gag DPAVDLL: vpx: - + - - + + + - - + - + - - + control Vpx control Vpx 10 -2 10 -1 10 0 10 1 10 2 contro l IFN-β Ga g WT Ga g -DPAVDLL HIV-1 transduced (% GFP + ) C Figure 3 Among VLP constituents, Vpx is necessary and sufficient to rescue HIV-1 from type I IFN.(A) MDDCs were treated with LPS for 24 hrs, then treated for 3 hrs with media or the indicated VSV-G-pseudotyped HIV-2 ROD or SIV MAC-251 VLPs, and finally challenged with a VSV-G-pseudotyped HIV-1 NL4-3 GFP reporter virus. Infectivity was measured by flow cytometry. (B) As indicated, 293T cells were co-transfected with a codon optimized SIV MAC251 vpx expression plasmid and HIV-1 GFP reporter vectors bearing either wild-type Gag or Gag with an engineered Vpx binding motif (DPAVDLL). Proteins from the cell lysate and from virion preparations were separated by SDS-PAGE and then immunoblotted with anti-Vpx or anti-p24 antibodies. (C) MDDCs treated with IFN-b for 24 h and were then challenged with VSV-G-pseudotyped HIV-1 GFP reporter vectors with wild-type HIV-1 Gag or HIV-1 Gag bearing the engineered Vpx binding motif (DPAVDLL). Both HIV-1 reporter vectors were produced in the presence of empty pcDNA3.1 plasmid or pcDNA3.1 containing a codon-optimized SIV MAC-251 vpx cDNA. Data are representative of one of at least three independent experiments. Error bars represent ± SD (n = 3). Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 4 of 16 confers optimal Vpx incorpo ration into viri ons [19-21,43,44]. Nonetheless, vpx expression in trans dur- ing HIV-1 virion production has been reported to result in some Vpx protein incorporation into HIV-1 virions with concomitant increase in the efficiency of MDM transduction by HIV-1 [12]. Vpx protein production directed by a codon-optimized vpx expression plasmid during HIV-1 virion production r esulted in detectable Vpx incorporation into HIV-1 virions (Figure 3B) and partial rescue of HIV-1 three-part vector transduction in MDDCs that had been treated 24 hrs previously with IFN-b (Figure 3C). When the Vpx binding motif from the carboxy terminus of SIV MAC Gag (DPAVDLL) was engineered into HIV-1 Gag, Vpx packaging into HIV-1 virions was more efficient (Figure 3B) and rescue from IFN-b by Vpx was 10-fold more effective than it was with the parent construct (Figure 3C). These results indicate that, of the SIV MAC VLP components, Vpx is sufficient to rescue HIV-1 transduction from the type 1 IFN-associated antiviral state in MDDCs. Vpx does not rescue HIV-2 or SIV MAC from the antiviral state As previously described [6,7,11,45], disruption of the vpx open reading frame severely attenuated the transduction of MDDCs by three-part SIV MAC vector (Figure 4A), confirming the importance of vpx for MDDC-transduc- tion in the absence of exogenous type 1 IFN or LPS. In contrast, when an antiviral state was established with exogenous IFN or LPS prior to virus challenge, vpx did not rescue transduction by SIV MAC or HIV-2, even when SIV MAC or HIV-2 VLPs provided additional Vpx in trans (Figure 4 and additional file 3, Figure S3); in parallel, the same SIV MAC VLPs rescued HIV-1 trans- duction from the antiviral state in a vpx-dependent fash- ion (Figure 4C). Additionally, HIV-1 VLPs bearing all HIV-1 accessory genes were unable to rescue either HIV-1 or SIV MAC from the antiviral state (Figure 4D and 4E). These experiments demonstrate that Vpx has the ability to rescue HIV-1, but not SIV MAC from the antiviral state. Rescue of HIV-1 from the antiviral state by Vpx is independent of DCAF1 Vpx associates with the DDB1/RBX1/CUL4A E3 ubiqui- tin ligase complex via interaction with DCAF1 [12,13,15]. SIV MAC replication in macrophages is com- promised by disruption of Vpx association with DCAF1 using vpx mutations Q76A or F80A, or by knockdown of DCAF1 or components of the DDB1/RBX1/CUL4A complex [12,13,15,35]. To address the role of DCAF1 and the associated E3 ubiquitin ligase complex in rescue of HIV-1 from t he antiviral state in MDDCs, the Q76A and F80A vpx mutations were introduced into a codon- optimized SIV MAC vpx expression construct. Both mutant proteins expressed as well as wild type Vpx (Fig- ure 5A) and were efficiently incorporated into SIV MAC VLPs (Figure 5B). As compared to the wild-type Vpx, the efficiency of HIV-1 rescue from the antiviral state in MDDCs by either mutant was reduced roughly 5-fold (Figure 5C). Nonetheless, both mutants retained the ability to rescue HIV-1 from the antiviral state 140-fold (Figure 5C), indicating that interaction with DCAF1 is not required for this activity. The importance of DCAF1 for vpx-mediated rescue from the antiviral state was examined directly by trans- ducing MDDCs with lentiviral vectors engineered to confer puromycin-resistance and to express RNA poly- merase II-driven, microRNA-based short hairpin RNAs targeting either DCAF1 or a control RNA [39,46]. Freshly isolated CD14 + monocytes were transduced in control HIV-1 VLPs S IVvpx + VLPs 10 -2 10 -1 10 0 10 1 SIV transduced (% GFP + ) control LPS SIV MAC vpx + D control HIV-1 VLPs S IVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 HIV-1 transduced (% GFP + ) control LPS HIV-1 E SIV MAC vpx + SIV MAC Δvpx 10 -3 10 -2 10 -1 10 0 10 1 SIV transduced (% GFP + ) control LPS IFN-β A SIVΔvpx VLPs SIVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 SIV transduced (% GFP + ) control LPS IFN-β SIV MAC vpx + B SIVΔvpx VLPs SIVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 HIV-1 transduced (% GFP + ) contro l LPS IFN-β HIV-1 C Figure 4 Vpx rescues HIV-1, but not SIV MAC or HIV-2, from the type I IFN response in MDDC.(A) MDDCs were treated with the indicated compounds for 24 h, and then challenged with VSV-G- pseudotyped, vpx + or Δvpx SIV MAC GFP reporter virus. (B, C) MDDCs were treated with the indicated compounds for 24 h, then treated with either VSV-G-pseudotyped vpx + or Δvpx SIV MAC-251 VLPs, and then challenged with either VSV-G-pseudotyped SIV MAC-239 (B)or HIV-1 NL4-3 (C) GFP reporter viruses. (D, E) MDDCs were treated with LPS, then treated with either media or VSV-G pseudotyped HIV-1 NL4- 3 or SIV MAC-239 VLPs (containing all accessory genes) for 3 h, and then challenged with either VSV-G-pseudotyped SIV MAC-239 (D)or HIV-1 NL4-3 (E) GFP reporter viruses. Data are representative of one of at least three independent experiments. Error bars represent ± SD (n = 3). Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 5 of 16 thepresenceofSIV MAC VLPs to increase the effective titer of the knockdown vectors. Cells were placed in GM-CSF and IL-4, and pools of puromycin-resistant cells were generated with each knockdown vector, as previously described [39,46]. Lysate from MDDCs that h ad been transduced with knockdown vector targeting DCAF1 was examined by Western blot. In contrast to the strong signal observed with the control knockdown cells, DCAF1 protein was undetectable in the DCAF1-knockdown cells (Figure 6A), even after cells had been treated with exogenous IFN-b. The ability of t he cells to respond to IFN-b was confirmed by showing the induction of Mx1 protein (Figure 6A). Despite this highly effic ient DCAF1 knock- down, little change was observed in the ability of Vpx to rescue HIV-1 transduction from the antiviral state established by IFN-b or by LPS (Figure 6B and 6C). Parallel experiments in MDDCs from the same donor showed that transduction with SIV MAC was efficiently blocked by IFN-b or by LPS (Figure 6C), demonstrating that the antiviral state had been we ll-established in these cells. control Vpx WT Vpx Q76A Vpx F80A Produce r cells SIV VLPs IB: Vpx IB: p27 IB: Vpx IB: p27 BA IP: DCAF1 IB: Vpx IP: DCAF1 IB: DCAF1 IB: DCAF1 IB: Vpx Vpx WT Vpx Q76 A Vpx F80A control SIVΔvpx VLPs SIVvpx WT VLPs S IVvpx Q76A VLPs SIVvpx F80A VLPs 10 -2 10 -1 10 0 10 1 10 2 HIV-1 transduced (% GFP + ) control LPS C Figure 5 SIV MAC Vpx association with DCAF1 (VPRBP) is dispensable for Vpx-mediated rescue of HIV-1 from the antiviral state.(A) 293T cells were transfected with FLAG-tagged DCAF1 and either wild type SIV MAC-251 Vpx or SIV MAC-251 Vpx containing the indicated alanine-substitution mutations that disrupt associated with DCAF1. Immune complexes were isolated from clarified, 0.5% CHAPSO detergent lysates using anti-FLAG antibody conjugated to Protein G magnetic beads. Panels show immunoblots (IB) of the immunoprecipiated (IP) proteins (top panels) and immunoblots of the inputs (bottom panels). (B) Immunoblots of wild-type Vpx and the indicated mutants incorporated into SIV MAC- 251 VLPs (top panels) and expression in the 293T producer cells (bottom panels). (C) MDDCs were treated with LPS, then treated with SIV MAC-251 VLPs containing wild-type Vpx or the indicated mutants, and challenged with an HIV-1 NL4-3 GFP reporter virus. Data represent one of at least three independent experiments. Error bars represent ± SD (n = 3). β β -actin DCAF1 control K D DCAF1 KD control K D DCAF1 KD IFN-β β control MX1 A HIV-1 + control HIV-1 + LPS S IV MAC vpx + + control SIV MAC vpx + + LPS 10 -1 10 0 10 1 10 2 %GFP + cells control K D DCAF1 KD C control IFN-β 10 0 10 1 10 2 HIV-1 transduced (% GFP + ) control KD DCAF1 KD B Figure 6 DCAF1 (VPRBP) knockdown does not prevent Vpx rescue of HIV-1 from the antiviral state in MDDCs. MDDCs were transduced with lentiviral knockdown vectors targeting either DCAF1, or a control RNA, in the presence of SIV VLPs. DCAF1 KD and control KD cells were then treated with IFN-b for 24 hrs, and lysates were probed in immunoblots with antibodies against the indicated proteins (A), or cells were challenged with a VSV-G- pseudotyped HIV-1 NL4-3 GFP reporter virus (B). (C) DCAF1 KD and control KD MDDCs were treated with LPS for 24 h, and challenged with either VSV-G-pseudotyped HIV-1 NL4-3 or SIV MAC-239 GFP reporter viruses. Data represent one of at least three independent experiments. Error bars represent ± SD (n = 3). Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 6 of 16 The IFN-specific, vpx-sensitive block to HIV-1 is in the MDDC nucleus Vpx is required for the synthesis of SIV MAC or HIV-2 cDNA after infection of MDDCs or MDMs [10,13,14]. VLPs bearing Vpx similarly increase the levels of nas- cent HIV-1 cDNA after infection of these cell types [10]. In the absence of exogenous IFN, Vpx + VLPs indeed increased the levels of full-length linear HIV-1 cDNA (Figure 7A). The increase in the levels of 2-LTR circles (Figure 7B) and Alu-PCR products (Figure 7C) were of comparable magnitude. Heat-inactivated virus and virions generated in the absence of Env were used as controls to demonstrate that the PCR products were a reflection of de novo cDNA synthesis in the target cells and were not the result of contaminating plasmid DNA carried over from the transfection used to gener- ate the viruses. These experiments indicate that, in the absence of exogenous IFN, the main effect of Vpx is to increase the efficiency of HIV-1 reverse transcription. When MDDCs were treated with IFN-a prior to chal- lenge with HIV-1, the magnitude rescue of full-length viral cDNA and 2-LTR circles by Vpx was identical to the magnitude rescue by Vpx in the absence of exogenous IFN (Figure 7D). In contrast, the magnitude rescue of proviral DNA by Vpx was at least 12-fold greater whe n MDDCs had been treated with exogenous IFN than with untreated MDDCs (Figure 7C and 7D). The magnitude of this rescue possibly underestimates the real diffe rence, since the Alu-PCR signal was below the limit of detection when DNA from IFN-treated cells was used as template, even after 50 cycles of amplifica- tion. These data indicate that the IFN-specific effect of Vpx in MDDCs occurs after the preintegration complex is transported to the MDDC nucleus. Conclusions The experiments presented here demonstrate that SIV- MAC /HIV-2 Vpx rescues HIV-1 from the antiviral state established by exogenous type I IFN or LPS in MDDCs. This phenotype is truly extraordinary in that Vpx offeredcompleterescueofHIV-1,aftertheantiviral state had been fully established, and the magnitude of the rescue approached 1000-fold. Surprisingly, the pre- sence of Vpx in SIV MAC or HIV-2 did not protect these viruses from IFN-b or LPS treatm ent, even when target cell MDDCs were treated with VLPs be aring additional Vpx prior to challenge with reporter virus. Although Vpx is not normal ly an HIV-1 accessory protein, it pro- vides a powerful tool that will aid attempts to identify new HIV-1 restriction factors that are elicited by IFN in dendritic cells. Elucidation of the mechanism by which Vpx rescues HIV-1 from the antiviral state would be aided enor- mously by an experimental system that exploits a cell line. Among cell lines tested, the most pronounced phe- notype was observed with the acute monocytic leukemia cell line THP-1 [47], which had been treated with phor- bol esters to promote differentiation into macrophages, as we reported previously to study Vpx and innate immune signaling [11,39]. The magnitude inhibition of HIV-1 transduction by LPS or IFN-b in THP-1 macro- phages [11,39] was 10-fold less than that seen in MDDC. Of greater concern, though, rescue of HIV-1 from the antiviral state by Vpx + VLPs in these cells was only 2 to 10-fold (data not shown). Ongoing mechanis- tic studies concerning the Vpx phenotype reported here, then, will likely not be possible with a cell line. HIV-1 transduction of monocyte-derived macrophages (MDMs) was also greatly stimulated by Vpx; although, in the absence of exogenous IFN, HIV-1 transduction efficiency was lower in these cells than in MDDCs (data not shown). A necessary consequence is that a smaller proportion of the Vpx effect in MDMs was specific to the antiviral state. In other words, the magnitude rescue of HIV-1 by Vpx following establishment of the antiviral state w ith exogenous IFN was most evident in MDDCs. Inthepresenceofexogenoustype1IFN,MDDCs A B C Full length 2-LTR Provirus 0 5 10 15 Fold rescue IFN-α Fold rescue control D Provirus (Alu-PCR) no env heat killed S IVΔvpx VLPs SIVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 control IFN-α ND ND ND Relative copy number 2-LTR circles no env heat killed SIVΔvpx VLPs SIVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 10 3 control IFN-α ND ND Relative copy number Full length linear cDNA no env heat killed SIVΔvpx VLPs SIVvpx + VLPs 10 -2 10 -1 10 0 10 1 10 2 10 3 control IFN-α ND ND Relative copy number Figure 7 SIV MAC Vpx rescues HIV-1 from the antiviral state in MDDC prior to establishment of the provirus. MDDCs were treated with IFN-a for 24 h, and then treated with SIV MAC VLPs or media for 3 h, and finally challenged with a VSV-G-pseudotyped HIV-1 NL4-3 GFP reporter virus. Total DNA was extracted from 5 × 10 6 MDDCs and qPCR was performed for HIV-1 full-length linear reverse transcription products (A), 2-LTR circles (B), and provirus (C). (D) Data from A, B, C, represented as (fold-rescue of HIV-1 by Vpx from IFN-a treatment) divided by (fold-rescue of HIV-1 by Vpx in the absence of exogenous IFN). Data represent one of at least three independent experiments. Error bars represent ± SEM (n = 4). Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 7 of 16 might express an HIV-1-specific, Vpx-sensitive, anti- viral effector at higher levels than do MDMs. Alterna- tively, constitutive expression levels of this putative fac- tor might be higher in MDMs. Viruses often encode factors that prevent establish- ment of the antiviral state. For example, hepatitis C virus, poliovirus, and rhinovirus proteases degrade MDA-5, RIG-I, IPS-1, and TRIF [48-53]. In the experi- mental system reported here, Vpx was administered after the antiviral state was fully established. Therefore, Vpx does not act by blocking induction of the antiviral state. This is consistent with the observation that vpx had no significant effect on the transcriptional induc- tion of luciferase reporters for critical innate immune factors, including IFN-b,NF-B, or AP-1 (additional file 4, Figure S4). Additionally, Vpx appears not to launch a global shut- down of the antiviral state. It caused no change in levels of MDDC cell surface markers for maturation, in IFN-b secretion and steady-state protein levels for MX1 and APOBEC3A, or in steady-state levels of mRNAs pro- duced by 8 ISGs (additional file 1, Figure S1). More importantly, Vpx did not rescue SIV MAC or HIV-2, indi- cating that t he antiviral state was v ery much intact fol- lowing exposure to Vpx. More likely, Vpx inactivates an HIV-1-specific antiviral effector that is induced by IFN . This inactivation might involve degradation, the same way that Vif promotes the degradation of APOBEC3G [30-32] or Vpu promotes the degradation of TETHERIN [54-56]. Alternatively, Vpx might sequester the putative factor, blocking it without assistance from ubiquitination machinery, as may also be the case with Vif and Vpu [57,58]. Though it has been known for over 20 years that type 1 IFN and LPS block HIV-1 infection of myeloid cells [40], the e ffector proteins responsible for the block to HIV-1 transduction of IFN-treat ed MDDCs is not known. Several ISG-encoded proteins inhibit HIV-1, APOBEC3G [59] and Tetherin [60,61] being prominent among them. These host restriction f actors pose obsta- cles to infection of sufficient importance that HIV-1 maintains two of its nine genes - vif and vpu,respec- tively - to counteract them. Neither Vif nor Vpu is require d for th e phenotype reported here since Vpx res- cued minimal HIV-1 vectors lacking all viral accessory proteins as efficiently as it rescued full HIV-1 virus. Additionally, the best-characterized phenotypes of Vif and Vpu require their pr esence during virion assembly and the experiments reported here likely involve effects of Vpx that are restricted to the target cell. TRIM5, anothe r restriction factor encoded by an ISG, is required for establishment of an antiviral state by LPS in MDDCs [39]. Nonetheless, endogenous human TRIM5 is unlikely to be a direct antiviral effector in the experiments reported here since inhibition of HIV-1 transduction by exogenous type 1 IFN is not reversed by TRIM5 knockdo wn [39]. Other TRIM proteins are encoded by ISGs [62], and some of these exhibit anti- viral activity [63]. TRIM22, for example, blocks HIV-1 LTR-directed transcription [64], but the putative anti- viral effector in IFN-treated MDDCs acts before integra- tion, as documented by Alu-PCR (Figure 7). Additio nally, TRIM22 does not bl ock transcript ion from the heterologous promoter (SFFVp) used in the trans- duction vectors here [64]. In the course of examining ISG expression levels in MDDCs it was observed that, in response to exogenous type 1 IFN or LPS, APOBEC3A mRNA levels increased nearly 10,000-fold and the protein levels also increased to an impressive extent ( additional file 1, Figure S1C). APOBEC3A is a nuclear protein [65,66] and therefore a reasonable candidate for the Vpx-sensitive, IFN-stimu- lated, anti-HIV-1 effector protein. Specific association of APOBEC3A with Vpx was not detected in co-transfec- tion experiments in 293T cells, and no effect on inhibi- tion of HIV-1 was observed when APOBEC3A knockdown was attempted with lentiviral vectors or with transfected double-stranded R NA oligonucleotides (data not shown). These findings are in contrast to reports that Vpx associates with APOBE C3A and that a vpx mutant that does not bind to APOBEC3A failed to stimulate HIV-1 infection of monocytes [67]. APO- BEC3A knockdown was also reported to render mono- cytes more permissive for HIV-1 [68]. These discrepancies with the results reported here might be due t o cell t ype differences, i.e, monocytes versus MDDCs, or other differences in methodology. Vpx was recently shown to bind to SAMHD1 and promote the degradation of this myeloid cell protein [69,70]. While SAMH D1 is clearly a Vpx-sensitive inhi- bitor of HIV-1 replication in myeloid cells, it does not appear to be the IFN-stimulated HIV-1 inhibitor described here. SAMHD1 knockdown in THP-1 cells results in more than 10-fold increase in HIV-1 replica- tion [70]; in contrast to the enormous effect of Vpx in IFN-treated MDDCs, HIV-1 infection of IFN-treated THP-1 cells increases only two to three- fold in response to Vpx. Both Vpr and Vpx bind DCAF1 (VPRBP) and associ- ate with the DDB1/RBX1/CUL4A E3 ubiquitin ligase complex [12,13,15,33-37,71,72]. Vpr might, therefore, be expected to interfere with Vpx binding to DCAF1 and the E3 complex. However, the presence of HIV-1 Vpr or SIV MAC Vpr did not significantly alter the ability of SIV MAC Vpx to protect HIV-1 from the antiviral state, underlying the unique ability of Vpx to protect HIV-1. The unexpected finding that Vpx mutant proteins that do not bind to DCAF1 (Figure 5A and references Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 8 of 16 [12,13,15,35]) retain the ability to rescue HIV-1 from exogenous IFN indicates that the DCAF1/DDB1/RBX1/ CUL4A E3 ubiquitin ligase complex is dispensable for the phenotype reported here. Consistent with this result was the demonstration that Vpx rescued HIV-1 in the presence of an effective DCAF1 knockdown (Figure 6). While the DCAF1/DDB1/RBX1/CUL4A E3 ubiquitin ligase complex, and Vpx, is clearly required for SIV MAC to infect human macrophages in the absence of exogen- ous type 1 IFN [12], Vpx interaction with DCAF1 was alsonotrequiredforHIV-1transductionofTHP-1 macrophages [11]. These results indicate that, if Vpx rescues HIV-1 from the antiviral state by promoting the degradation of an antiviral effector, it does so by recruit- ing a yet-to-be-identified E3 ubiquitin ligase complex. As previously reported [10,13,14], Vpx had a large effect on HIV-1 reverse transcription in transduced MDDCs (Figure 7). An additional effect of Vpx was observed, though, that was specific to the cells that had been treated with exogenous type 1 IFN: Vpx overcame a block to HIV-1 transduction that occurred after the virus had entered the target cell nucleus (Fig- ure 7). Thus, it may be that Vpx protects HIV-1 from more than one antiviral factor. The first factor is con- stitutively expressed in myeloid cells and blocks reverse transcription. The second factor is induced by IFN and acts in the nucleus to block transduction. HIV-1 CA and IN, two proteins essential at this stage of the HIV-1 replication cycle [28,73,74], would be likely targets of this antiviral factor. To date, attempts to demonstrate the importance of these proteins by transferring Vpx-responsiveness using chimeric viruses have not been successful due to the poor infectivity of these constructs in highly permissive cell lines, let alone in M DDCs. Why does Vpx protect HIV-1, and not SIV MAC or HIV-2, from the antiviral state in MDDCs? A number of scenarios are possible. It might be that there is an IFN-inducible, HIV-1-specific inhibitor, which is sup- pressed by Vpx. This factor might be induced by the recently reported HIV-1-specific, cryptic sensor in MDDCs [75]. In this case, one would need to invoke an additional, IFN-induced, SIV MAC -specific factor, which isnotsuppressedbyVpx.Alternatively, there might be a single IFN-induced inhibitor of both viruses, from which Vpx offers protection to HIV-1 but not to SIV- MAC . Whichever scenario is correct, identification of antiviral factors such as these has the potential to guide development of new drugs for inhibiting HIV-1 replica- tion in the clinical context. Additionally, given the criti- cal role of dendritic cells at the interface between the innate and acquired immune systems [76,77], identifica- tion of such factors may aid attempts to understand how the innate immune system detects HIV-1, and assist efforts to stimulate acquired immune responses to HIV-1 [39,78]. Methods Ethics statement Buffy-coats obtained from anonymous blood donors were provided by the Blood Transfusion Center of the Hematology Service of the University Hospital of Gen- eva by agreement with the Service, after approval of our project by Ethics Committee of the University Hospital of Geneva (Ref# 0704). Chemicals and drugs The following compounds were used at the given final concentrations: Ultrapure LPS from E. coli K12 (100 ng/ mL), poly(I:C) (25 μg/mL, or 2 μg/mL when complexed with Lipofectamine 2000 (Invitrogen)), and poly(dA:dT) (2 μg/mL) were obtained from Invivogen. Recombinant, human IFN-b (10 ng/mL) a nd recombinant, hu man IFN-a2a (10 ng/mL) were obtained from PBL Interfer- onSource. All other chemicals and drugs were obtained from Sigma-Aldrich, unless otherwise noted. Cell lines and primary cell cultures HEK-293 and 293T cells were obtained from American Type Culture Collection (ATCC) and were grown in Dulbecco’s modified Eagle medium (D-MEM) (high glu- cose) (Invitrogen) supplemented with 10% fetal bovine serum (FBS) (Hyclone), 1 × MEM Non-Essential Amino Acids (NEAA) Solution (Invitrogen), and 1 × Gluta- MAX-I (Invitrogen). 293T cells were p eriodica lly grown in cell culture medium containi ng 500 μg/mL Geneticin (Invitrogen) to maintai n expression of the SV40 large T antigen. THP-1 cells were obtained from ATCC and main- tained in RPMI-1640 (Invitrogen) supplemented with 10% FBS, 20 mmol/L HEPES (Invitrogen), 1 × MEM NEAA, and 1 × GlutaMAX-I. In order to differentiate THP-1 monocytes into macrophage-like cells, THP-1 cells were counted, centrifuged at 200 × g for 10 min, and resuspended at a concentration of 1 × 10 6 cells/mL in fresh cell culture medium containing 100 ng/mL phorbol 12-myristate 13-acetate (PMA). Cells were pla- ted into each well of a sterile tissue cul ture plate (2 mL culture/well of a 6-well plate or 200 μL culture/well of a 96-well flat-bottom plate) and allowed to differentiate for 24 h, at which poin t the PMA-containing medium was removed and fresh cell culture medium (without PMA) was added. The cells were rested for an additional 48 h before use. Peripheral blood mononuclear cells (PBMCs) were iso- lated from buffy coats prepared from healthy, anon- ymous donors using Ficoll-Paque Plus (GE Healthcare) following the protocol supplied by Miltenyi Biotec. Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 9 of 16 CD14 + cells (monocytes) were enriched from PBMCs by positive selection using CD14 MicroBeads (Miltenyi Bio- tec) with purity ro utinely greater than 95%, as deter- mined by flow cytometry after staining with PE anti- human CD14 (BD Biosciences). Enriched CD14 + cells were counted, centrifuged at 200 × g for 10 min, and resuspended in RPMI-1640 supplemented with 10% FBS, 20 mmol/L HEPES, 1 × MEM NEAA, and 1 × Glu- taMAX-I, at a concentration of 1 × 10 6 cells/mL. In order to generate monocyte-derived macrophages (MDM), recombinant, human GM-CSF (R&D Systems) was added to the cell suspension to a final concentration of 50 ng/mL, and in order to generate monocyte-derived dendritic cells (MDDC), recombinant, human IL-4 (R&D Systems) was added to a final concentration of 25 ng/mL along with 50 ng/mL GM-CSF. CD14 + cells were allowed to either differentiate into MDDCs in the pre- sence of GM-CSF and IL-4 fo r 4 d, or into MDMs in the presence of GM-CSF alone for 10 d, before use. The following antib odies were used for flow cytometry: APC anti-CD86 (BU63) was from EXBIO; FITC anti-CD1a (HI149), PE anti-CD209 (DC-SIGN) (DCN46), and APC-anti-CD83 (HB15e) were from BD Biosciences. Iso- type controls were from Miltenyi Biotec. All primary cells and cultured cell lines were main- tained in cell culture media w ithout penicillin or strep- tomycin, and were cultured at 37°C in a humidified incubator containing 5% carbon dioxide. Plasmids, Vectors, and Viruses SIV MAC-251 vpx,HIV-2 ROD vpx,SIV SMM-PBj vpx,and SIV AGM-TAN vpr were codon-optimized for expression in human cells using services provided by Sloning Bio- Technology GmbH (Puchheim, Germany). See addi- tional file 5, Table S1 for the codon-optimized nucleic acid sequences. The codon optimized cDNAs were cloned into pcDNA3.1(-) (Invitrogen) by PCR using the primer pairs listed in additional file 6, Table S2. Alanine substitution mutations were introduced into the codon- optimized SIV MAC-251 vpx cDNA by overlapping PCR, using the primer sets detailed in additional file 6, Table S2. APOBEC3A, APOBEC3A:Myc:6 × His, APOBEC3G, and APOBEC3G:Myc:6 × His expression constructs were provided by Dr. Klaus Strebel (National Institute of Allergy and Infectious Diseases, NIH). FLAG:HA: AU1:DCAF1 and F LAG:HA:AU1:DDB1 expression con- structs were provided by Dr. Jacek Skowronski (Case Western Reserve University). pFSGW, an HIV-1-based transfer vector with EGFP expression under the control of the spleen focus-form- ing virus (SFFV) long terminal repeat (LTR), as well as gag-pol and VSV G expression plasmids, are described elsewhere [39]. pSIV3+, a SIV MAC-251 gag-pol expression plasmid [79], and pSIV3+Δvpx, generated by digest with BstB1 and religation after blunting ends with DNA Poly- merase I, Large (Klenow) Fragment (New England Bio- Labs), introducing a premature stop codon at amino acid 25 of vpx, were provided by Dr. Andrea Cimarelli (École Normale Supérieure de Lyon). pNL4-3 Nef NA7 : GFP (CCR5-tropic), which bears the V3 loop of the CCR5-tropic 92TH014-2 HIV-1 strain and where Nef NA7 is fused to EGFP [80,81]. pNL4-3.GFP.E- [82] and pNL4-3.Luc.E- [83] are pNL4-3 with an env - inacti- vating mutation and EGFP or luciferase, respectively, cloned in place of nef. The HIV-2 and HIV-2Δvpx packaging plasmids, as well as the HIV-2 GFP transfer vector, are described elsewhere [10]. p8.9NDSB is a minimal HIV-1 packaging plasmid [84]. The SIV MAC Vpx binding motif (DPAVDLL) was generated and introduced into HIV-1 Gag p6 by overlapping PCR and cloned into the BglII and BclI sites of p8.9NDSB using the following primers: p6 BglII 5’ :5’ -TAGGGAA- GATCTGGCCTTCCCACAA-3’,p6Vpxins3’:5’-TAG- CAGATCCACAGCTGGGTCTTCTGGTGGGGCTG TTGGCTCTGG-3’ ,p6Vpxins5’:5’ -GACCCAG CTGTGGATCTGCTAGAGAGCTTCAGGTTTGGGGA AGA-3’ ,p6BclI3’ :5’- ATGAGTATCTGATCATACT GTCTTACTT-3’ .SIV MAC-239 env - GFP is described elsewhere [85]. psSIV-GAE is pSIV-GAE [86], a SIV- MAC-251 transfer vecto r expre ssing GFP, where the cyto- megalovirus (CMV) promoter driving EGFP expression was replaced with the SFFV LTR, amplified by PCR from pFSGW. Production of viruses, vectors, and virus-like particles (VLPs) Viruses, minimal vectors, and VLPs were produced by transfection of 293T cells using Lipofectamine 2000 (Invi- trogen), according to the manufacturer’s instructions. For three-part vector systems, the following DNA ratio was used: 4 parts transfer vector: 3 parts packaging plasmid: 1 part envelope. For two-part virus systems a 7:1 ratio was used (7 parts env - virus: 1 part envelope). For VLPs, a 7: 1 ratio was used (7 parts gag-pol expression plasmid: 1 part envelope). 16 h after transfection the transfection medium was replaced with fresh target-cell medium. 48 h after transfection the supernatant was collected, centrifuged at 200 × g for 5 min, filt ered thro ugh a sterile 0.45 μmsyr- inge filter (Millipore), and stored in 1 mL aliquots at -80° C. When comparing viruses, vectors, or VLPs, samples were normalized by single-cycle infectivity assays on HEK- 293 cells and/or the reverse transcriptase (RT) activity pre- sent in the viral supernatant by qRT-PCR [87]. RNAi in primary human monocyte-derived dendritic cells and macrophages To generate stable microRNA-based shRNA knock- downs in primary human MDDC or MDM, human Pertel et al. Retrovirology 2011, 8:49 http://www.retrovirology.com/content/8/1/49 Page 10 of 16 [...]... for 10 min and 45 cycles of 95°C for 15 s and 60°C for 1 min The Page 11 of 16 following TaqMan Gene Expression Assays were used: APOBEC3A (Hs00377444_m1), APOBEC3G (Hs00 222 415 _m1), CCL2 (Hs0023 414 0_m1), CCL8 (Hs00 2 716 15_m1), CUL4A (Hs00757 716 _m1), CXCL10 (Hs00 17 1042_m1), DDB1 (Hs0 017 2 410 _m1), IFIT1 (Hs00 3566 31_ g1), IFIT2 (Hs00533665_m1), IFNB1 (Hs 01 077958_s1), IL6 (Hs00985639_m1), MX1 (Hs00 18 2073_m1),... Primitive hematopoietic cells resist HIV -1 infection via p 21 J Clin Invest 2007, 11 7:473-4 81 doi :10 .11 86 /17 42-4690-8-49 Cite this article as: Pertel et al.: Vpx rescues HIV -1 transduction of dendritic cells from the antiviral state established by type 1 interferon Retrovirology 2 011 8:49 Submit your next manuscript to BioMed Central and take full advantage of: • Convenient online submission • Thorough... Cul4-DDB1 [VprBP] E3 ubiquitin ligase to modulate cell cycle Proc Natl Acad Sci USA 2007, 10 4 :11 778 -11 783 35 Le Rouzic E, Belaidouni N, Estrabaud E, Morel M, Rain JC, Transy C, Margottin-Goguet F: HIV1 Vpr arrests the cell cycle by recruiting DCAF1/ VprBP, a receptor of the Cul4-DDB1 ubiquitin ligase Cell Cycle 2007, 6 :18 2 -18 8 36 Schrofelbauer B, Hakata Y, Landau NR: HIV -1 Vpr function is mediated by interaction... sensor for the retrovirus capsid lattice Nature 2 011 , 472:3 61- 365 40 Kornbluth RS, Oh PS, Munis JR, Cleveland PH, Richman DD: Interferons and bacterial lipopolysaccharide protect macrophages from productive infection by human immunodeficiency virus in vitro J Exp Med 19 89, 16 9 :11 37 -11 51 41 Panne D, Maniatis T, Harrison SC: An atomic model of the interferon-beta enhanceosome Cell 2007, 12 9 :11 11- 112 3 42... PD: Tetherin inhibits HIV -1 release by directly tethering virions to cells Cell 2009, 13 9:499- 511 Sheehy AM, Gaddis NC, Choi JD, Malim MH: Isolation of a human gene that inhibits HIV -1 infection and is suppressed by the viral Vif protein Nature 2002, 418 :646-650 Neil SJ, Zang T, Bieniasz PD: Tetherin inhibits retrovirus release and is antagonized by HIV -1 Vpu Nature 2008, 4 51: 425-430 Van Damme N, Goff... 2006, 13 :9 91- 994 Marin M, Rose KM, Kozak SL, Kabat D: HIV -1 Vif protein binds the editing enzyme APOBEC3G and induces its degradation Nat Med 2003, 9 :13 98 -14 03 Sheehy AM, Gaddis NC, Malim MH: The antiretroviral enzyme APOBEC3G is degraded by the proteasome in response to HIV -1 Vif Nat Med 2003, 9 :14 04 -14 07 Pertel et al Retrovirology 2 011 , 8:49 http://www.retrovirology.com/content/8 /1/ 49 32 Yu X, Yu Y, ... with the indicated compounds for 24 h Upregulated surface expression of CD86 on MDDC was then determined by flow cytometry (B) MDDCs were treated with vpx+ or Δvpx SIVMAC-2 51 VLPs for 3 h, and then treated with LPS for 24 h The MDDC media was then collected and added to HL 116 cells, which carry the luciferase gene under the control of the IFNinducible 6 -16 promoter, for 7 h The HL 116 cells were then... 2006, 10 3:60 01- 6006 52 Drahos J, Racaniello VR: Cleavage of IPS -1 in cells infected with human rhinovirus Journal of virology 2009, 83 :11 5 81- 115 87 53 Barral PM, Sarkar D, Fisher PB, Racaniello VR: RIG-I is cleaved during picornavirus infection Virology 2009, 3 91: 1 71- 176 54 Mangeat B, Gers-Huber G, Lehmann M, Zufferey M, Luban J, Piguet V: HIV -1 Vpu neutralizes the antiviral factor Tetherin/BST-2 by binding... NR: Incorporation of Vpr into human immunodeficiency virus type 1 virions: requirement for the p6 region of gag and mutational analysis J Virol 19 93, 67:7229-7237 Wu X, Conway JA, Kim J, Kappes JC: Localization of the Vpx packaging signal within the C terminus of the human immunodeficiency virus type 2 Gag precursor protein J Virol 19 94, 68: 616 1- 616 9 Jenkins Y, Pornillos O, Rich RL, Myszka DG, Sundquist... Virology 2006, 344:88-93 Yamashita M, Perez O, Hope TJ, Emerman M: Evidence for direct involvement of the capsid protein in HIV infection of nondividing cells PLoS pathogens 2007, 3 :15 02 -15 10 Manel N, Hogstad B, Wang Y, Levy DE, Unutmaz D, Littman DR: A cryptic sensor for HIV -1 activates antiviral innate immunity in dendritic cells Nature 2 010 , 467: 214 - 217 Banchereau J, Steinman RM: Dendritic cells and the . 200 400 600 800 10 00 200 400 600 800 10 00 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 10 0 10 1 10 2 10 3 10 4 B control IFN- β 10 -1 10 0 10 1 10 2 control SIV MAC . Vpx rescues HIV -1 from the antiviral state established by exogenous type I IFN or LPS in MDDCs. This phenotype is truly extraordinary in that Vpx offeredcompleterescueofHIV -1, aftertheantiviral state. exogen- ous type 1 IFN [12 ], Vpx interaction with DCAF1 was alsonotrequiredforHIV-1transductionofTHP -1 macrophages [11 ]. These results indicate that, if Vpx rescues HIV -1 from the antiviral state by promoting